A semiconductor wafer includes a silicon carbide wafer and an epitaxial layer, which is disposed at a surface of the silicon carbide wafer and made of silicon carbide. The semiconductor wafer satisfies a condition that a waviness value is equal to or smaller than 1 micrometer. The waviness value is a sum of an absolute value of a value and an absolute value of a value . A highest height among respective heights of a plurality of points with reference to a surface reference plane within a light exposure area is denoted as the value . A lowest height among the respective heights of the points at the epitaxial layer with reference to the surface reference plane within the light exposure area is denoted as the value .

There is provided a reverse-blocking semiconductor device that has a simple configuration, that is capable of improving a yield in a manufacturing process, and that secures a reverse withstand voltage by using a Schottky junction, and there is provided a method for manufacturing the reverse-blocking semiconductor device. A semiconductor device is provided that includes a first conductivity type semiconductor layer that has a front surface, a rear surface on an opposite side of the front surface, and an end surface, a MIS transistor structure formed at a front-surface portion of the semiconductor layer, a first electrode that forms a Schottky junction with a part of the semiconductor layer in the rear surface of the semiconductor layer, and an electric-field relaxation region that is formed to reach the rear surface from the front surface of the semiconductor layer in a peripheral region surrounding an active region in which the MIS transistor structure is formed and that is either a high-resistance region having higher resistance than the semiconductor layer or a second conductivity type impurity region.

A method for forming a polycrystalline semiconductor layer includes forming a plurality of spacers over a dielectric layer, etching the dielectric layer using the plurality of spacers as an etch mask to form a recess in the dielectric layer, depositing an amorphous semiconductor layer over the plurality of spacers and the dielectric layer to fill the recess, and recrystallizing the amorphous semiconductor layer to form a polycrystalline semiconductor layer.

A system and method for fabricating an orifice in a multi-layered semiconductor substrate and singulation of the semiconductor substrate includes adding a sacrificial layer of material to a first surface of a semiconductor substrate; subsequently, removing a first radius of a first depth of material from the semiconductor substrate along a direction normal to the first surface, the removal of the first depth of material uses a first removal technique that removes the first depth of material; and removing a second radius of a second depth of material from the semiconductor substrate along the direction normal to the first surface based on the removal of the first depth of material, the removal of the second depth of material uses a second removal technique.

A method of forming concurrently openings in a substrate or wafer or a portion of substrate or wafer openings therein at least one of the openings has a relatively high aspect ratio and another one of the openings has a relatively low aspect ratio, the method comprising: bonding the substrate or wafer or a portion of substrate or wafer to a carrier substrate; forming a ring trench in the substrate or wafer or in a portion of the substrate or wafer, the ring trench having an outer perimeter that corresponds an outer perimeter of the another one of the openings having said relatively low aspect ratio and having an inner perimeter spaced from the outer perimeter by a predetermined distance; forming an opening in said substrate or wafer or in a portion of substrate or wafer having said high aspect ratio concurrently with the forming of the ring trench; and separating the substrate or wafer or in a portion of the substrate or wafer from the carrier substrate.

A semiconductor device has an active region through which a main current flows, a gate ring region surrounding a periphery of the active region, a source ring region surrounding a periphery of the gate ring region, and a termination region surrounding a periphery of the source ring region. The semiconductor device has a semiconductor substrate of a first conductivity type, a first semiconductor layer of the first conductivity type, a second semiconductor layer of a second conductivity type, and further, in the active region, first semiconductor regions of the first conductivity type, a gate insulating film, first gate electrodes, an interlayer insulating film, a first first-electrode, a first plating film, and a second electrode. The semiconductor device has, in the source ring region, a second first-electrode provided at a surface of the second semiconductor layer, and a second plating film provided on the second first-electrode.

A semiconductor device of an embodiment includes a silicon carbide layer having first and second plane, the silicon carbide layer including trench having a first portion and a second portion, the second portion having a width smaller than the first portion, an n-type first silicon carbide region, a p-type second silicon carbide region between the first silicon carbide region and the first plane, a p-type third silicon carbide region between the second silicon carbide region and the first plane and having a p-type impurity concentration lower than the second silicon carbide region, an n-type fourth silicon carbide region between the third silicon carbide region and the first plane, and an n-type fifth silicon carbide region between the second portion and the second silicon carbide region and having an n-type impurity concentration higher than the first silicon carbide region; and a gate electrode in the trench.

A semiconductor device including a semiconductor substrate of a first conductivity type, a first semiconductor layer of the first conductivity type, provided at a front surface of the semiconductor substrate and having an impurity concentration lower than that of the semiconductor substrate, a second semiconductor layer of a second conductivity type, selectively provided on the first semiconductor layer, a first semiconductor region of the first conductivity type, selectively provided in the second semiconductor layer and having an impurity concentration higher than that of the semiconductor substrate, a trench penetrating the first semiconductor region and the second semiconductor layer, to reach the first semiconductor layer, and a gate electrode provided in the trench, via a gate insulating film. The trench has a sidewall that includes a terrace portion, surface roughness of the terrace portion being at most 0.1 nm.

A semiconductor device of an embodiment includes a SiC layer including a first trench, a second trench having first and second regions, an n-type first SiC region, a p-type second SiC region, an n-type third SiC region, a p-type fourth SiC region between the first trench and the first SiC region, and a p-type fifth SiC region between the second trench and the first SiC region and having a first portion and a second portion, a gate electrode in the first trench, a first electrode in the second trench, and a second electrode. A distance between the first trench and the first region is greater than a distance between the first trench and the second region, the first portion is separated from the fourth SiC region, the second portion contacts the fourth SiC region, the first region contacts the first portion, and the second region contacts the second portion.

Temperature controlled polishing pads are disclosed. In one aspect, a CMP system includes the use of any type of atomizing system to cool or remove energy and/or heat from the polishing pad of a CMP system. The atomizing system can use of any liquid medium in combination of any compressed gas through an orifice to cool or remove the energy and/or heat from the pad, thereby allowing for higher removal rates during CMP.